GCOOS Meetings 24-27 April 2006 Biloxi, MS

1. The Global Ocean Observing System (GOOS) and the U.S. Integrated Ocean Observing System (IOOS); with focus on the National Backbone GCOOS Meetings 24-27 April 2006 Biloxi, MS

2. Outline • Global Ocean Observing System • U.S. Integrated Ocean Observing System - Background - The Global Module - The Coastal Module - The National Backbone

3. Global Ocean Observing System(GOOS)

4. Global Ocean Observing System(GOOS) • GOOS is an end-to-end system of observations, data management, and production and delivery of products/services. • GOOS is being coordinated by United Nation agencies with the participation of some 100 ocean nations. • Together with the World Weather Watch, Global Atmospheric Watch, Global Climate Observing System and Global Terrestrial Observing System, GOOS is an element of the Global Earth Observation System of Systems (GEOSS).

5. The GOOS Modules The Global Ocean Observing System (GOOS) has been designed and is being implemented in two modules: • The global module is designed to monitor, predict, and understand marine surface conditions and climate variability/change; and • The coastal module is designed to sustain healthy marine ecosystems, ensure human health, promote safe and efficient marine transportation, enhance national security, and predict and mitigate against coastal hazards. The U.S. contribution to GOOS is called the Integrated Ocean Observing System (IOOS).

6. U.S. Integrated Ocean Observing System (IOOS)

7. Background

8. 1998 U.S. Congress Called for anIntegrated Ocean Observing System (IOOS)Provide Data/Info Required for More Rapid Detection & Timely Prediction of State Changes • Improve the safety & efficiency of marine operations • Improve homeland security • Mitigate effects of natural hazards more effectively • Improve predictions of climate change & their effects • Minimize public health risks • Protect & restore healthy ecosystems in coastal environments more effectively • Sustain living marine resources 1 System, 7 Goals

9. Framework for IOOS • Ocean.US formed in 2000 • Governed by a federal Executive Committee • Prepare & maintain IOOS Development Plans • Coordinate interagency implementation • 2004 U.S. Commission on Ocean Policy • Implement the IOOS • Implement ecosystem-based management approaches to natural resources & water quality • Strengthen the Regional Approach • President’s Ocean Action Plan • Enhance Ocean Leadership & Coordination • Establish IOOS as part of GEOSS • Optimize & Harmonize Use & Conservation of Ocean, Coastal & Great Lakes • Manage Coasts & their Watersheds • Establish strong partnerships among stakeholders

10. Integrated Ocean Observing System (IOOS) An End–to–End System that Routinely Provides Data & Information Specified by Groups that Use, Depend on, Manage or Study Oceans & Coasts GOOS (1) Analysis, Modeling End To End (2) Data Management & Communications (3) Observing In Situ & Remote Sensing

11. Integrated End – to – End SystemRapid Access to Diverse Data from Many Sources Data Telemetry Data Management & Communications Modeling & Analysis Products & Services Observations Satellites Maritime Navigational Services Aircraft • Metadata standards • Data discovery • Data transport • Online browse • Data archival Search & Rescue Coastal Flooding & Erosion Fixed Platforms Data Management Beach Closures Ships Water Management Drifters & Floats Nutrient Management AUVs Fisheries Management 11

12. Ecosystem-Based, Adaptive Management • Rapid & Repeated Detection of changes • over a broad spectrum of time-space scales • Timely Predictions of such changes Tune the flow of environmental data & information to the Time scales on which decisions should be made WE DO NOT HAVE THIS CAPABILITY TODAY

13. Why? • Cultural divides • Inefficient, ineffective data management • Under sampling in time, space & ecological complexity • Lack of capacity for rapid data acquisition & analysis

14. U.S. IOOS Multi – Scale Hierarchy of Observations Global Ocean Climate Component GOOS/GCOS Coastal Ocean Component GLs GoA NE NW MAB Regional Observing Systems SE H Isl C Cal Go Mex S Cal Carrib National Backbone Low Resolution High

15. The Global Module

16. Global Component of the GOOSIntegrates Remote & In Situ SensingAn International Collaboration

17. Broad Objectives of Ocean Component • Monitoring and detection of climate change • Seasonal-to-interannual climate prediction • Marine and weather forecasts • Short-range ocean forecasts • Understanding decadal variations • Support of scientific research • Routine ocean state estimation International coordination and oversight of the global ocean component is by the WMO-IOC Joint Technical Commission for Oceanography and Marine Meteorology; U.S. participation is significant.

18. Key Actions • Full implementation of the surface and subsurface observing networks • Designate and support national agents for implementation and establish research-operational partnerships • Timely, free, unrestricted data exchange and comprehensive data management procedures • International standards for metadata for essential climate variables • Develop more cost effective two-way communication technologies • Develop integrated global climate product needs

19. Multi-year Phased Implementation Plan (representative milestones) 2001 2002 2000 2003 2004 2005 2006 2007 2008 2009 2010 Real-time Stations Initial GCOS Subset 170 148 126 106 Tide Gauges 91 79 67 67 69 51 56 1250 1250 1250 1250 1250 1250 779 787 807 671 Number of buoys 975 Surface Drifting Buoys 119 97 104 115 Number of moorings 84 87 Tropical Moored Buoys 77 77 79 79 79 High resolution and frequently repeated lines occupied 51 51 51 45 34 28 Ships of Opportunity 27 26 26 24 23 3000 3000 3000 3000 3000 Number of floats 544 20 31 2300 Argo Floats 1572 923 Number of observatories, flux, and ocean transport stations 89 49 42 78 41 60 37 15 35 Reference Stations 29 54 Ice buoys, drifting and Moored stations 85 31 78 64 29 29 30 30 Arctic System 54 37 34 31 Repeat Sections Committed, One inventory per 10 years 31 31 29 1 Ocean Carbon Network 0 0 27 27 24 24 830 830 730 340 Days at sea (NOAA contribution) Dedicated Ship Time 640 531 370 370 497 497 497 9 Product evaluation and feedback loops implemented (NOAA contribution) 9 9 9 3 8 2 System Evaluation 7 0 1 1 Initial Ocean Observing System Milestones including international contributions 100 88 77 System % Complete 45 40 34 30 66 Total System 55 53 48 2001 2002 2000 2003 2004 2005 2006 2007 2008 2009 2010

20. 56% complete

21. GCOS Climate Reference Tide Gauge Stations 54% complete

22. The Coastal Module

23. Coastal Component National Backbone • FederalAgencies • Responsible • EEZ & Great Lakes • Core variables required by • regions & Federal Agencies • Network of sentinel & • reference stations • Standards/Protocols Regional COOSs • Regional Associations • Responsible • Involve private & public • sectors • Inform Federal Agencies • of user needs • Enhance the backbone • based on user needs • Incorporate sub–regional • systems

24. 11 Groups Funded by NOAA Coastal Services Center to Establish Regional Associations (RAs) ACOOS NANOOS GLOS NERA CenCOOS MACOORA SCCOOS SECOORA PacIOOS GCOOS CaRA

25. IOOS & Data Management • Data Management and Communications (DMAC) subsystem - a primary integrating mechanism for IOOS • Framework to link diverse observing systems into an integrated, interoperable data-sharing network • DMAC Plan: evolving recommended data and metadata standards, protocols, and operating practices

26. Geophysical Sea surface meteorological variables Land–Sea Stream flows Sea level Surface waves, currents Ice distribution Temperature, Salinity Bathymetry Biophysical Optical properties Benthic habitats Chemical pCO2 Dissolved inorganic nutrients Contaminants Dissolved oxygen Biological Fish species, abundance Zooplankton species, abundance Phytoplankton species, biomass (ocean color) Waterborne pathogens IOOS Coastal Backbone Core Variables

27. IOOS Coastal Component High Priority Research & Pilot Projects • Surface current mapping • Product: real–time surface current maps • HF–radar, remote & in situ sensing • Data assimilation–numerical modeling • Space–based remote sensing • Improve chl algorithms for ocean color • Increase spatial, temporal, & spectral resolution • Sea surface salinity • Aircraft remote sensing of near shore environments • LIDAR • Coupled physical–water quality/ecosystem models • Ecosystem – Based Management • Glider development for in situ sensors • In situ sensors for core variables • Chemical & biological

28. IOOS Summary: Current Status • 1st Annual IOOS Development Plan • Global ocean– climate component being implemented • Initial backbone in place • Sub– regional coastal ocean observing systems funded • DMAC Plan completed • Regional groups funded to • Form Regional Associations • Engage User Groups: Public & Private Sectors • Establish RCOOSs • Government support • Current Funding: ~ $ 125 M • Executive order • Legislation in Congress to Authorize Additional Funding

29. The National Backbone

30. The National Backbone of the IOOS • What is it? • How will it be specified? • How will it be implemented? • How will it be funded? Based on a Presentation by Tom Malone, Ocean.US Office

31. Background • Spatial boundaries are blurred intentionally • Global & coastal components overlap. • RCOOSs overlap w/ the National Backbone & each other. • Fixed boundaries are needed for funding & accountability only. • At this time, RCOOS development is focused on regional needs (or should be). • As an integrated component of the IOOS, the Initial National Backbone (NB) exists in concept only. • The First IOOS Development Plan recommends • Existing operational assets for an initial observing subsystem for the NB; • Road map for developing the DMAC subsystem • As the DMAC subsystem comes into being, the NB will transition from concept to reality. • At this time, the recommended NB assets are funded & operated by federal agencies for the most part.

32. What is the NB in Concept? • Initial Observing Subsystem Infrastructure • Measures the core variables in the nation’s Exclusive Economic Zone & Great Lakes • Transmits DMAC-compliant data to data assembly centers routinely & reliably • Remote sensing: sea surface temperature only • In situ sensing: Sparse network of sentinel & reference stations

33. Programs Recommended for NB

34. Programs Recommended for NB(continued)

35. Societal Goals & NB Programs

36. Societal Goals & NB Programs(continued)

37. Next Steps • Initial NB recommended in the 1st IOOS Development Plan • Does not include elements of regional or subregional observing systems at this time. • Phased development of the NB • Stage 1: Identify Building Blocks (Today) • Initial NB as recommended in 1st IOOS DP & IOOS DP: FY 2006 – 2008 • Stage 2: Integration (2006 – 2008) • Initial DMAC subsystem implemented • All elements of the IOOS becoming DMAC compliant. • Regional & subregional elements incorporated into the NB based on user needs & recommendations in IOOS Development Plans • Stage 3: Transition to a fully user–driven system (2008 – ) • Must be DMAC compliant & support products & services requiring data integration • RCOOSs become integral part of the IOOS as a whole

38. How Will It Be Specified & Implemented? • Ocean.US Responsible for Design Specifications & Development Plans • IOOS Implementation Conferences • Federal Agencies  Regional Associations • IOOS Development Plans • Ocean.US  Joint Subcommittee on Ocean Science and Technology (JSOST) • Federal Agencies & RAs responsible for implementation

39. How Will It Be Funded? Non-Federal Funding RCOOSs Federal Funding RCOOSs Federal Funding National Backbone Federal Funding RA Administration

40. Thank You • GOOS International http://ioc.unesco.org/goos/ • GOOS U.S. http://www-ocean.tamu.edu/GOOS/ • IOOS – Ocean.US http://ocean.us/